Glutathione conjugation of chlorobenzylidene malononitriles in vitro and the biotransformation to mercapturic acids in rats.

The glutathione conjugation of 2-chloro-, 3-chloro-, 4-chloro- and 2,6-dichlorobenzylidene malononitrile (chloroBMNs) was investigated in vitro. In incubation mixtures containing rat liver cytosol (9000 g), the decrease in the initial amount of glutathione due to the various chloroBMNs ranged from 40 to 60% and occurred both enzymatically and spontaneously at physiological conditions (37 degrees C, pH 7.4). 2,6-DichloroBMN, however, depleted glutathione largely spontaneously (38 +/- 3%). The steric hindrance of the two chlorosubstituents probably plays an important role during the glutathione-S-transferase catalyzed reaction. The hydrolysis of the chloroBMNs to the corresponding chlorobenzaldehydes and malononitrile was studied in a mixture of buffer pH 7.4 and ethanol. The rate of hydrolysis of 2,6-dichloroBMN was slower than those of the related chloroBMNs. This means that 2,6-dichloroBMN will be the most stable compound in the presence of water. Only IP administration of 2-chloroBMN (CS) to adult male Wistar rats gave enhancement of urinary thioether excretion. A thioether could be isolated and was identified as the N-acetyl-S-[2-chlorobenzyl]-L-cysteine. The quantity of this benzylmercapturic acid in the urine of rats amounted to 4.4% dose (0.07 mmol/kg, n = 12). After IP administration of 2-chloro- and 3-chlorobenzaldehyde to rats benzylmercapturic acid excretion in the urine was found to be 7.6 and 1.1% of the dose, respectively. Administration of the related 4-chloro- and 2,6-dichlorobenzaldehyde, however, resulted in no urinary mercapturic acid excretion.(ABSTRACT TRUNCATED AT 250 WORDS)

Biotransformation of 1,2-dibromopropane in rats into four mercapturic acid derivatives.

1,2-Dibromopropane was administered orally in doses of 50-350 mg/kg to male Wistar rats. Four mercapturic acids were identified in urine by GC/MS, viz. N-acetyl-S-(2-oxopropyl)-L-cysteine (I), N-acetyl-S-(2-hydroxypropyl)-L-cysteine (II), N-acetyl-S-(1-carboxyethyl)-L-cysteine (III), and N-acetyl-S-(2-bromo-2-propenyl)-L-cysteine (IV). Mercapturic acid IV was a minor metabolite which could only be measured at doses of 200 mg/kg or higher. In 24 hr, urinary excretion of mercapturic acids amounted to about 36% of the dose (11% I, 21% II, 4% III, 0.2% IV). No dose dependency was found up to the highest dose. A unified scheme is proposed for the metabolism of 1,2-dibromopropane in the rat, which accounts for the identified mercapturic acids. The role of direct glutathione conjugation in the route leading to the major metabolite II, presumably involving thiiranium ion formation, is discussed. This route probably is biologically not very important because of the absence of detectable activity of 1,2-dibromopropane toward glutathione S-transferases in vitro, the very low mutagenicity of 1,2-dibromopropane, and the high mutagenic activity of N-acetyl-S-(2-bromopropyl)-L-cysteine methyl ester which was studied as a model compound for direct conjugation.

Mercapturic acid formation in the marmoset (Callithrix jacchus).

Benzylmercapturic acid is a major metabolite of [methylene-14C]benzyl chloride in the marmoset, as in the rat. The excretion of the minor metabolites benzylmercapturic acid sulphoxide and benzylcysteine accounted for a greater proportion of the dose than in the rat. Excretion of hippuric acid as a metabolite of benzyl chloride was variable in the marmoset. Acetylation of S-benzyl- and S-pentyl-L-cysteine to the corresponding mercapturic acids was extensive in the marmoset. Trace amounts of the sulphoxides of these acids were also excreted.

Metabolic coordination of liver and kidney in mercapturic acid biosynthesis in vivo.

When S-carbamido(14C)methyl glutathione, a model compound of glutathione S-conjugate, was administered i.v. to mice, radioactivity accumulated in the kidney within 1 to 2 min and then decreased gradually during the following 10 to 15 min with concomitant increase in hepatic radioactivity. Most hepatic radioactivity was accounted for by S-carbamidomethyl cysteine and its N-acetyl derivative, a mercapturic acid. The i.v. administration of S-carbamido(14C)methyl cysteine resulted in rapid and predominant accumulation of radioactivity in the liver. In both cases, the radioactive urinary metabolites were fully accounted for by N-acetyl-S-carbamidomethyl cysteine. N-Acetyl-S-carbamido(14C)methyl cysteine administered to mice were accumulated preferentially in the kidney and was excreted into urine very rapidly. These results suggest the following series of events: glutathione S-conjugate accumulated mainly in the kidney and is hydrolyzed into its component amino acids, presumably by gamma-glutamyl transferase and some peptidase(s) on the renal brush border membranes. The cysteine S-conjugate which is formed in the tubular lumen is reabsorbed and transferred to the liver, acetylated to form N-acetylcysteine S-conjugate, and excreted in the urine. Thus, renal hydrolysis of glutathione S-conjugates seems to be coordinated with acetylation in liver and with mercapturic acid biosynthesis in vivo.

The oxidative metabolism of 1-bromopropane in the rat.

1. The metabolism of 1-bromopropane in the rat has been re-investigated. The previously known metabolites have been isolated and confirmed as the three mercapturic acids N-acetyl-S-propyl cysteine, N-acetyl-S-propyl cysteine-S-oxide and N-acetyl-S-(2-hydroxypropyl)cysteine. 2. Three further metabolites have been isolated from the urine of rats treated with 4-bromopropane. These have been identified as 3-bromopropionic acid and the mercapturic acids N-acetyl-S-(3-hydroxypropyl)cysteine and N-acetyl-S-(2-carboxyethyl)cysteine. 3. The metabolites of 3-bromopropanol and 3-chloropropanol in the rat have been shown to be the mercapturic acids N-acetyl-S-(3-hydroxypropyl)cysteine and N-acetyl-S-(2-carboxyethyl)cysteine and the corresponding 2-carboxyethyl halide. 4. Studies with 1-bromopropane and the 3-halopropanols in vitro indicate that oxidation of C3 and C2 of 1-bromopropane occurs before conjugation of the alkyl group with glutathione. The implications of these studies are discussed in relation to the mechanism of the biosynthesis of the S-(2-hydroxyalkyl)mercapturic acid metabolites derived from the alkyl halides.

Glutathione conjugation and mercapturic acid formation in the developing rat, in vivo and in vitro.

1. The levels of GSH-S-epoxidetransferase (GSH-S-transferase E, EC 2.5.1.18), gamma-glutamyl transpeptidase (EC 2.3.2.2) and S-substituted cysteine N-acetyltransferase have been measured in the liver and kidney of neonatal to adult rats. 2. GSH-S-epoxidetransferase and S-substituted cysteine N-acetyltransferase activities were less than 10% of the adult values in neonatal rats, rising gradually to reach adult values at about 40 days of age. Renal gamma-glutamyl transpeptidase activity was 27% of the adult value 2 days after birth and increased after 15 days reaching adult levels by 40 days. 3. The percentages of the doses of 1,2-epoxy-3-(p-nitrophenoxy)propane (ENPP) and of 1,2-epoxybutane, administered at the same dose level to rats aged 4 days to adult, excreted as the corresponding mercapturic acids in 24 h, were not significantly different. 4. Adult and 10 day old rats doses at the same dose level with ENPP excreted N-acetyl-S-[2-hydroxy-3-(p-nitrophenoxy)propyl]-L-cysteine (ENPP-MA) at the same rate. 5. In addition to ENPP-MA, dosed rats under 13 days of age excreted the corresponding substituted cysteine. 6. The correlation between results in vitro and in vivo is discussed.

Herbicide metabolism by glutathione conjugation in plants.

Glutathione conjugation of foreign compounds is the first step in the mercapturic acid pathway for the detoxication and elimination of toxic compounds in mammals. Plants have been found to metabolize and detoxify some organic herbicides by glutathione conjugation, but the terminal products seem to be different from that in mammals. The terminal product in plants appears to be insoluble residue and not the mercapturic acid derivative which is normally excreted in mammals. The insoluble residue very likely remains in the plant body during the life of the plant. The differences in metabolism between plants and animals may have been necessitated by the lack of an excretory system in plants.

Biosynthesis of mercapturic acids from allyl alcohol, allyl esters and acrolein.

1. 3-Hydroxypropylmercapturic acid, i.e. N-acetyl-S-(3-hydroxypropyl)-l-cysteine, was isolated, as its dicyclohexylammonium salt, from the urine of rats after the subcutaneous injection of each of the following compounds: allyl alcohol, allyl formate, allyl propionate, allyl nitrate, acrolein and S-(3-hydroxypropyl)-l-cysteine. 2. Allylmercapturic acid, i.e. N-acetyl-S-allyl-l-cysteine, was isolated from the urine of rats after the subcutaneous injection of each of the following compounds: triallyl phosphate, sodium allyl sulphate and allyl nitrate. The sulphoxide of allylmercapturic acid was detected in the urine excreted by these rats. 3. 3-Hydroxypropylmercapturic acid was identified by g.l.c. as a metabolite of allyl acetate, allyl stearate, allyl benzoate, diallyl phthalate, allyl nitrite, triallyl phosphate and sodium allyl sulphate. 4. S-(3-Hydroxypropyl)-l-cysteine was detected in the bile of a rat dosed with allyl acetate.